Effect of a novel negative temperature early-strength agent in improving concrete performance under varying curing temperatures

• Published in: Case Studies in Construction Materials Vol. 21; p. e03748
• Main Authors: Zhao, Yasong, Zhao, Yuxin, Zhu, Zhaohui, Chen, Gaofeng, Wu, Huixia, Liu, Cheng, Gao, Jianming
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.12.2024; Elsevier
• Subjects: Concrete profermance; Curing temperature; Hydration products; Microtructure; Negative temperature early-strength agent; Concrete profermance; Microtructure; Negative temperature early-strength agent; Hydration products; Curing temperature
• ISSN: 2214-5095; 2214-5095
• DOI: 10.1016/j.cscm.2024.e03748

This study investigates the effect of a novel negative temperature early-strength agent (NEA) in enhancing concrete performance under varying curing temperatures, with a discussion on the underlying mechanism through analysis of hydration products and microstructure.The results indicate NEA markedly accelerates early cement hydration, reduces setting time, and enhances compressive strength. Moreover, the efficacy of NEA is more pronounced at lower temperatures. With an optimal dosage of 3 %, the incorporation of NEA leads to a remarkable 285.9 % increase in compressive strength at 28 days under −5°C curing temperature. Despite accelerating cement hydration can induce increased chemical shrinkage, NEA effectively mitigates early freezing expansion under negative temperature and significantly diminishes chloride ion permeability. Higher temperatures facilitate early cement hydration but also compromise long-term hydration continuity. Consequently, the highest hydration degree and loweast porosity are observed at 28 days under 5°C curing temperature. NEA's air-entraining component introduces numerous superfine pores into the paste, augmenting early pore volume while optimizing pore structure. As the early-strength component fosters hydration, these pores undergo further filling and refinement, ultimately reducing the total pore volume at 28 days. This study provides insights into optimizing concrete performance in cold environments. •A novel negative temperature early-strength agent in concrete was developed.•NEA markedly accelerates early cement hydration under negative temperature.•NEA mitigates early freezing expansion and diminishes chloride ion permeability.•NEA's air-entraining component optimizes pore structure and reduces late porosity.